含有酚羟基的吖嗪类荧光探针的阴离子识别与传感研究

设计合成了含有酚羟基的萘吖嗪类荧光探针分子,利用紫外-可见吸收光谱和荧光发射光谱研究了探针分子的阴离子识别和光化学传感性能。研究结果表明,该探针分子可以通过比色（紫外-可见吸收光谱）和荧光发射光谱双通道识别检测氟离子。该探针分子是一类比率型阴离子荧光探针,作用方式为探针分子酚羟基的去质子化作用,这种激发态质子转移（ESIPT）是探针分子呈现比率荧光特性的原因。通过本实验不但可以让学生掌握紫外-可见吸收光谱和荧光发射光谱仪的使用方法,还能培养学生在分子识别与光化学传感领域的科研兴趣。     

新型有机荧光探针分子的设计合成及在生物医学中的应用

近年来,荧光化学传感器以其高选择性、高灵敏度、实时原位监测、简便快捷等优点,受到人们的普遍欢迎.开发一些具有高灵敏度、高选择性、实时原位检测性能的荧光化学传感器,特别是开发一些具有实际应用价值的荧光化学传感器,一直都是人们追求的目标.论文根据分子识别和光化学传感的基本原理,结合生物医学检测的需要,设计了几种能够在水相中识别生物医学上重要生物活性分子的荧光探针分子.主要工作和结果概述如下.     

含巴比妥结构荧光探针的合成及其应用研究

汞离子污染已经严重危害生态环境和人类健康,发展具有高选择性、高灵敏度且能应用于水性环境中汞离子的检测探针具有重要的研究意义.以水杨醛为原料,设计、合成一种含有巴比妥结构单元的激发态分子内质子转移(ESIPT)型荧光探针;机理研究预测汞离子与探针形成了一种类似于"(胸腺嘧啶)T-Hg-T"的结构,从而可以高选择性地识别汞离子,并且在4～20μmol·L~(-1)之间,探针的荧光强度与汞离子浓度呈现非常好的线性关系.     

一种基于偶氮水杨醛酰腙的CN-探针

设计合成了一种基于偶氮苯基团的简单而高效的比色探针L1,并利用紫外-可见吸收光谱考察其对阴离子(F-,Cl-,Br-,I-,AcO-,H2PO4-,HSO4-,ClO4-和CN-)的识别性能。结果表明:探针L1在DMSO/H2O(5∶5,V/V)的含水体系中,可以实现对CN-单一选择性识别;且加入CN-时,溶液颜色立刻由无色变为红色,而加入其它阴离子则无变化,说明该探针能够实现对CN-的裸眼识别。另外,该探针对CN-的检测灵敏度较高,最低检测限达到了1.3μmol·L-1。此外,我们制作了负载有探针分子L1的试纸条,能够更加方便快捷的检测CN-。     

基于有机小分子的焦磷酸根荧光探针研究进展

焦磷酸根(PPi)作为一种重要的生物功能阴离子在生命科学、环境科学、药物领域和化学过程等方面起着非常重要的作用.鉴于荧光分析具有操作简便、灵敏度高等突出优点,设计合成高效的PPi荧光探针成为近年来超分子化学研究的热点之一.综述了近年来PPi荧光识别与传感的多种设计策略与原理,主要包括基于荧光增强或淬灭型识别,激基缔合物识别,荧光指示剂置换,静电或氢键作用识别等.DPA-金属离子络合物,尤其是DPA-Zn2+络合物,作为识别基团对PPi有着显著的亲和性和选择性识别能力.DPA-Zn2+络合物与多种荧光团或者荧光指示剂组合而形成的化学传感体系已经被广泛应用于PPi荧光识别与传感.     

对二甲氨基苯甲酸的阴离子识别应用研究

采用紫外分光光度法和荧光分光光度法研究了主体分子对二甲氨基苯甲酸与HPO42-、SO42-、H2PO4-、ClO4-、HSO4-、NO3-、BF4-、PF6-、F-、Cl-和Br-等11种阴离子客体的识别作用.发现在乙腈溶液中,该主体分子对二价阴离子HPO42-和SO42-表现了强亲和力和高选择性;并对一价阴离子F-和H2PO4- 具有一定的响应能力;而与一价阴离子ClO4-、HSO4-、NO3-、BF4-、PF6-、Cl-和Br-几乎没有作用.结果表明主客体分子本身的酸碱性和阴离子的负电荷数目是影响主体分子对阴离子识别性能的主要因素.     

水溶性共轭聚合物在生物传感中的应用

水溶性共轭聚合物在化学、医学、生命科学以及材料科学等领域中备受研究者们的关注,利用其独特的光化学和光物理性质,研究者们开展了一系列创新性研究并取得了重大的研究进展,进而拓展了聚合物的应用范围.共轭聚合物是一种由多个重复发光单元通过彼此间共轭而形成的高分子化合物,通过对其结构的精准调控,可以获得具有不同性能的功能性分子.其中,通过改变其主链结构,可以获得具有不同吸收和发射波长的荧光探针;通过对侧链结构修饰以水溶性基团和/或选择性识别分子,可以实现与特定靶标间的静电作用或者特异性结合,进而实现选择性识别的目的.本文综述了近年来水溶性共轭聚合物在生物传感中的应用,主要介绍了水溶性共轭聚合物在DNA检测、蛋白质检测、细胞和细菌的检测与区分以及细胞成像等方面的研究进展.     

基于酰腙和酚羟基的阴离子受体的合成及其在含水介质中的阴离子比色识别性能

设计合成了一系列基于羟基和氨基的酰腙类受体分子.利用紫外-可见吸收光谱及1HNMR考察了其与F-,Cl-,Br-,I-,CH3COO-,H2PO4?,HSO4?,ClO?4等阴离子的作用.结果表明,该类受体分子在DMSO溶液中能较好地比色识别F-,CH3COO-,H2PO4?,其中受体2在含水介质中[V(DMSO)∶V(H2O)=7∶3]能选择性比色识别CH3COO-.1HNMR滴定实验研究了受体分子与阴离子之间的作用,结果表明受体分子与阴离子之间以氢键作用方式相结合.     

一种2-乙酰基吡嗪-罗丹明B衍生物的合成及其对Ni~(2+)的识别

分子光谱法具有灵敏度高、操作简单等优点,发展简便、快捷、对镍离子(Ni~(2+))具有高度选择性的探针具有非常重要的意义。本文以金属离子诱导罗丹明酰胺衍生物反应开环的策略,设计并合成了对Ni~(2+)检测具有单一选择性识别的紫外吸收探针。同时,该探针可对水溶液中的Ni~(2+)实现"裸眼"识别。此外,该探针对Ni~(2+)具有较高的灵敏度,其对水溶液中Ni~(2+)的检测限为0.5μmol/L,表明该探针可用于Ni~(2+)的检测分析。     

生物硫醇荧光探针的研究进展

生物硫醇(包含半胱氨酸、高半胱氨酸和谷胱甘肽)在生命活动中扮演了重要的角色,其浓度的异常变化与某些疾病息息相关,因此对硫醇的检测具有重要意义.荧光探针因具有灵敏度高、时空分辨率好、无损伤、可视化等优势,在生物硫醇的检测方面得到了高度重视.利用硫醇在分子结构上的共同点(含巯基的氨基酸)和差异(分子大小、亲核性、空间位阻、细胞内含量),可通过迈克尔加成、亲核芳基取代、加成环化等反应实现对硫醇的选择性检测.综述了近3年来硫醇荧光探针领域的研究进展.首先介绍了对硫醇有选择性识别的荧光探针,随后分类讨论了对半胱氨酸、高半胱氨酸和谷胱甘肽各具有特异性检测的荧光探针,并重点介绍了分子设计、识别机理、荧光性质和成像应用,初步探讨了部分探针在监测细胞生命活动中的作用,同时还对本领域的发展提出了展望.     

基于分子识别的细菌检测研究进展

以抗体-抗原免疫识别、 核酸碱基互补配对识别以及核酸适体-配体识别这3种分子识别方式分类, 综述了近几年基于分子识别的细菌检测研究工作进展, 总结了细菌检测相关研究存在的一些挑战, 并展望了该领域的发展前景.     

Supramolecular Sensing of a Chemical Warfare Agents Simulant by Functionalized Carbon Nanoparticles

Real-time sensing of chemical warfare agents by optical sensors is today a crucial target to prevent terroristic attacks by chemical weapons. Here the synthesis, characterization and detection properties of a new sensor, based on covalently functionalized carbon nanoparticles, are reported. This nanosensor exploits noncovalent interactions, in particular hydrogen bonds, to detect DMMP, a simulant of nerve agents. The nanostructure of the sensor combined with the supramolecular sensing approach leads to high binding constant affinity, high selectivity and the possibility to reuse the sensor.     

Recoverable solution reaction of HiPco carbon nanotubes with hydrogen peroxide

There is increasing interest in developing single-walled carbon nanotubes (SWNTs)-based optical biosensors for remote or in vitro and in vivo sensing because the near-IR optical properties of SWNTs are very sensitive to surrounding environmental changes. Many enzyme-catalyzed reactions yield hydrogen peroxide (H(2)O(2)) as a product. To our knowledge, there is no report on the interaction of H(2)O(2) with SWNTs from the optical sensing point of view. Here, we study the reaction of H(2)O(2) with an aqueous suspension of water-soluble (ws) HiPco SWNTs encased in the surfactant sodium dodecyl sulfate (SDS). The SWNTs are optically sensitive to hydrogen peroxide in pH 6.0 buffer solutions through suppression of the near-IR absorption band intensity. Interestingly, the suppressed spectral intensity of the nanotubes recovers by increasing the pH, by decomposing the H(2)O(2) into H(2)O and O(2) with the enzyme catalase, and by dialytically removing H(2)O(2). Preliminary studies on the mechanisms suggest that H(2)O(2) withdraws electrons from the SWNT valence band by charge transfer, which suppresses the nanotube spectral intensity. The findings suggest possible enzyme-assisted molecular recognition applications by selective optical detection of biological species whose enzyme-catalyzed products include hydrogen peroxide.     

Receptors for tetrahedral oxyanions

This review covers the field of anion recognition from the perspective of tetrahedral oxyanion recognition. The bulk of the attention is devoted to metal-free systems that are able to effect the recognition, binding or transport of phosphate and sulfate. Particular emphasis is devoted to design criteria that allow for discrimination and selectivity. In this context, a variety of recognition motifs are discussed and, within each receptor class, general paradigms that allow for the construction of receptor systems with high affinity and specificity are noted.     

Fast screening of ketamine in biological samples based on molecularly imprinted photonic hydrogels

A novel label-free colorimetric chemosensor was developed for handy and fast screening of ketamine with high sensitivity and specificity based on molecularly imprinted photonic hydrogels (MIPHs) that combined the colloidal-crystal with molecular imprinting technique. The unique inverse opal arrays with a thin polymer wall in which the imprinted nanocavities of ketamine moleculars distributed allowed high sensitive, quick responsive, specific detection of the target analyte, and good regenerating ability in an aqueous environment. Due to the hierarchical inverse opal structural characteristics, the specific ketamine molecular recognition process can induce obvious swelling of the MIPHs to be directly transferred into visually perceptible optical signal (change in color) which can be detected by the naked eye through Bragg diffractive shifts of ordered macroporous arrays. In order to enhance the recognition ability in aqueous environments, the MIPHs were designed as water-compatible and synthesized in a water–methanol system. The molecular recognition mechanisms were investigated. The proposed MIPHs were successfully employed to screen trace level ketamine in human urine and saliva samples, exhibiting high sensitivity, rapid response, and specificity in the complex matrix. The smart chemosensor can provide an effective alternative for fast screening of ketamine on the spot for forensic investigations.     

氢键识别超分子聚合物的新进展

近年来,由于氢键作用对聚合物的热力学性质、微观自组装、结晶及液晶行为的重要影响,氢键识别在超分子聚合物的分子设计与结构控制方面的应用受到广泛关注。本文系统介绍了氢键识别体系的类型与性质,以及分子结构、分子内氢键对氢键识别强度的影响,讨论了羧酸与吡啶间氢键识别体系、与核苷相关的氢键识别体系以及四重氢键识别体系在超分子聚合物中的最新应用,主要介绍了氢键识别超分子聚合物的合成、结构、性质及功能。     

Optical sensing based on analyte recognition by enzymes,carriers and molecular interactions

Despite the tremendous variety of methods suitable for sensing applications, we face the fact that chemical sensors displaying sensitivity, selectivity and reversibility are still scarce and are mostly confined to low-molecular-weight species. Obviously, it is not the lack of optical (or other) transduction methods that limit the performance of present day sensor desingns, but rather the insufficient selectivity of the recognition process, particularly in the field of sensors for organic and bioorganic species. The use of enzymes, ion carriers and natural or synthetic receptor/carriers which can under go specific interactions with the species to be recognized (such as through hydrogen bonding or charge-transfer interaction) can result in specific recognition and, consequently, sensing. Examples for optical sensing schemes for clinically or biologically important species including enzyme substrates, metabolites, drugs, alkali and ammonium ions and other will be given. In enzyme-based sensors various options exist: depending on which species is immobilized, assays for substrates (such as glucose, ethanol, lactate or creatine), enzymes (such as esterases) or inhibitors (such as organophosphates) can be designed. In addition, the intrinsic optical properties of certain enzymes, coenzymes or metabolites can be utilized for sensing purposes, a fact that presents an interesting alternative to enzyme sensors with chemical transducers.Notwithstanding the selectivity of biocatalytic sensors, their stability and sensitivity is moderate. Bioorganic synthetic molecules which can recognize and reversibly bind other species offer an attractive alternative, particularly in terms of stability. However, quite a different situation is found in such cases because receptors, in contrast to enzymes, do not “digest” their substrates. Hence, while the steady-state response in enzyme-based sensors is a result of kinetic equilibration, substrate binding in non-metabolizing receptors results in thermodynamic equilibration. However, most existing receptors (except antibodies) lack the unique specificity of enzymes. On the other side, new bioorganic molecules and stable receptor/carriers along with polymer materials of proper permeation selectivity can help to overcome current limitations of protein-based systems. Neutral ion carriers, which may be considered as ion receptors, are a useful example of sometimes highly specific recognition/carrier molecules with excellent stability. Unfortunately, no receptor /carrier molecules of similar specificity do exist yet for most other organic and clinical parameters of interest. There is an obvious need for new and stable molecules suitable for specific recognition of low-molecular weight organic species.We will report on the use of such new receptor/carrier molecules, the respective sensor materials, and how the process of recognition can be coupled to optical transduction. Such receptors/carriers also allow other kinds of discriminations: if, for instance, it is enantio-selective (i.e. preferably binds one species out of a pair of optical isomers), a fairly specific recognition of enantiomers of biogenic amines (such as some drugs and biogenic amines) will become possible. Specific examples will also be given of new types of sensors based on recognition by charge-transfer interaction, through-space interaction and hydrogen bonding, with fair specificity for thiamine, penicilline, nitrate, salicylate and cholic acids. Finally, current problems and the significant challenges for sensors research in the 1990s will be discussed.     

杯芳烃衍生物对阴离子的识别作用

综述了杯芳烃衍生物对阴离子识别作用的研究进展。详细介绍了杯芳烃衍生物的化学结构修饰和分子结构以及其通过氢键和静电等作用对卤素、有机酸根、金属酸根等阴离子的识别作用,并对其应用前景进行了展望。     

Cavitand‐Grafted Silicon Microcantilevers as a Universal Probe for Illicit and Designer Drugs in Water

The direct, clean, and unbiased transduction of molecular recognition into a readable and reproducible response is the biggest challenge associated to the use of synthetic receptors in sensing. All possible solutions demand the mastering of molecular recognition at the solid–liquid interface as prerequisite. The socially relevant issue of screening amine‐based illicit and designer drugs is addressed by nanomechanical recognition at the silicon–water interface. The methylamino moieties of different drugs are all first recognized by a single cavitand receptor through a synergistic set of weak interactions. The peculiar recognition ability of the cavitand is then transferred with high fidelity and robustness on silicon microcantilevers and harnessed to realize a nanomechanical device for label‐free detection of these drugs in water.